JP6338545B2 - Work vehicle - Google Patents

Description

  The present invention relates to a work vehicle capable of displaying information related to wheel tread adjustment.

  2. Description of the Related Art Conventionally, work vehicles capable of displaying information related to tread adjustment when adjusting the tread of a wheel are known. Patent document 1 discloses this kind of work vehicle.

  The work vehicle of Patent Document 1 drives a liquid crystal display unit, an operation unit capable of setting a tread set value, a sensor for detecting a current value of the tread, and an actuator so that the tread becomes the set value. An ECU capable of performing the operation. This ECU is configured to display the current value and set value of the tread on the liquid crystal display unit.

  Patent Document 1 assumes that the current value and set value of the tread can be easily confirmed by this configuration.

JP 2014-205440 A

  Patent Document 1 discloses a case where the tread of a wheel is changed by an actuator. According to this configuration, a tread value desired by an operator can be easily realized. However, when the work vehicle does not include an actuator for changing the tread, the operator needs to change the tread manually.

  When manually adjusting the tread of the wheel, the operator actually performed the work after confirming in the instruction manual or the like where the member should be attached in order to realize the desired tread. However, it is necessary to take out the instruction manual from the storage location and read the corresponding location, which reduces the convenience of work.

  In this regard, Patent Document 1 does not disclose or suggest any case where the operator manually adjusts the tread of the wheel.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to enable an operator to easily confirm the mounting position of a member for realizing an intended tread when the tread of a wheel is manually adjusted. It is to provide a work vehicle.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

According to an aspect of the present invention, a work vehicle having the following configuration is provided. In other words, the work vehicle includes a rear wheel provided with an actuator for automatically adjusting the tread of the wheel, and a front wheel whose tread is adjusted via a fixing member having a plurality of attachment positions. The work vehicle includes a display unit that displays information about the tread. The display unit can display information related to a tread of the rear wheel provided with the actuator. The display unit can display a plurality of tread values of the front wheels in association with the attachment positions for realizing the tread values.

  As a result, when the operator manually adjusts the tread of the wheel, it is possible to easily grasp the mounting position of the fixing member corresponding to the intended tread only by confirming the display on the display unit provided by the operator. . Therefore, the tread adjustment of the wheel can be performed easily and accurately.

The work vehicle preferably has the following configuration. That is, the work vehicle is input by operating the operation unit that can be operated by an operator so as to select any one of the plurality of tread values displayed on the display unit . And a control unit that controls the adjustment of the tread of the rear wheel in response to an instruction . The display unit graphically displays a plurality of the mounting positions of the fixing member for adjusting the tread of the front wheel, and displays the mounting position corresponding to the tread value selected by an operator's operation in the other It can be displayed in a manner different from the mounting position.

  Thereby, when adjusting the tread of a wheel, by selecting the tread intended by the operator, the mounting position of the fixing member corresponding to the tread is displayed in an easy-to-understand manner. Therefore, the tread adjustment of the wheel can be performed more accurately.

The work vehicle preferably has the following configuration. That is, the front wheel comprises a disk and a rim fixed to the disk, the. The rim is configured to be fixable to the disk at a plurality of fixed positions. The tread value displayed on the display unit changes according to the fixed position of the rim and the disc.

  Thus, even when the tread is changed depending on the fixed position between the rim and the disk, the operator can accurately know the correspondence between the tread value and the mounting position.

The work vehicle preferably has the following configuration. That is, the front wheel comprises a disk and a rim fixed to the disk, the. The rim is configured to be fixable to the disk at a plurality of fixed positions. The display unit can display a plurality of tread values at at least one of the mounting positions in association with the fixed positions for realizing the plurality of tread values.

  Thus, the operator can easily confirm how the rim should be fixed to the disk in relation to the desired tread value. As a result, the efficiency of the tread adjustment work can be improved.

  In the work vehicle, it is preferable that the display unit displays the tread value that can be adapted to the work device among the plurality of tread values when the work device is mounted on a vehicle body.

  Thereby, by referring to the display on the display unit and attaching the wheel, it is possible to prevent contact between the attached wheel and the work device.

The side view of the tractor concerning one embodiment of the present invention. The top view of a tractor. The top view which shows the support structure of the front wheel of a tractor. The top view which shows the support structure of the rear wheel of a tractor. The block diagram which shows the electric constitution regarding tread adjustment. The perspective view which shows the structure of a monitor apparatus. The figure which shows the home screen displayed with a monitor apparatus. The figure which shows the tread adjustment screen in the case of moving the rear wheel of both sides. The figure which shows the tread adjustment screen in the case of moving the rear wheel only on one side. The figure which shows the screen displayed with a monitor apparatus in order to support attachment of a tie rod fixing bolt and a front axle fixing bolt among the tread adjustment work of a front wheel. The figure which shows the screen displayed with a monitor apparatus in order to assist adjustment of a cutting angle stopper bolt among the tread adjustment work of a front wheel. The figure which shows a mode that the fixed position of the rim | limb and disc of a front wheel is input into a monitor apparatus.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a side view of a tractor 100 according to an embodiment of the present invention. FIG. 2 is a plan view of the tractor 100. In the following description, “left”, “right”, and the like mean left and right in the direction in which the tractor 100 moves forward.

  A tractor 100 as a work vehicle for farm work shown in FIG. 1 is configured to be able to perform various types of work by attaching various work devices such as plows and loaders as necessary.

  As shown in FIG. 2 and the like, the tractor 100 includes a body 2, a pair of left and right front wheels (wheels) 3L and 3R that support the front of the body 2, and a pair of left and right rear that supports the rear of the body 2. And wheels 4L and 4R. The pair of front wheels 3 and the pair of rear wheels 4 are attached to the front axle 30 and the rear axle 40 so that the respective treads can be adjusted (details will be described later).

  As shown in FIG. 1, a bonnet 5 is disposed in the front portion of the airframe 2. An engine 6 is accommodated in the bonnet 5. The engine 6 is configured as a diesel engine and functions as a drive source for the tractor 100. However, the configuration of the engine 6 is not limited to the above, and may be configured as, for example, a gasoline engine.

  A cabin 7 for an operator to board is installed behind the bonnet 5. Inside the cabin 7, a handle 8 for an operator to steer, a driver seat 9 for the operator to sit, and various operation devices for performing various operations are provided.

  Examples of the operation device include the monitor device 50, the throttle lever 61, the shift lever 62, the PTO switch 63, and a plurality of hydraulic operation levers 64 shown in FIG. These operating devices are arranged on the right side of the driver seat 9. The monitor device 50 is configured to display various information of the tractor 100. The throttle lever 61 is for setting the rotational speed of the engine 6. The shift lever 62 is for changing the speed ratio of the transmission 12. The PTO switch 63 can connect / disconnect power transmission from a PTO shaft (power take-off shaft) (not shown) protruding from the rear end of the transmission 12 to a work machine such as a loader attached to the machine body 2. The hydraulic operation lever 64 can switch and operate a hydraulic external take-off valve (not shown). The PTO shaft is configured to drive the working device connected to the body 2 of the tractor 100 by rotating with the power transmitted from the engine 6.

  A chassis 10 of the tractor 100 is provided at the lower part of the body 2. The chassis 10 includes a body frame 11, a transmission 12, a front axle 13, a rear axle 14, and the like.

  The body frame 11 is a support member at the front portion of the tractor 100, and supports the engine 6 directly or via a vibration isolation member.

  The transmission 12 decelerates the power from the engine 6 and transmits it to the front axle 13 and the rear axle 14. When the operator operates the shift lever 62, the gear ratio of the transmission 12 can be adjusted.

  The front axle 13 is configured to transmit power input from the transmission 12 to the front wheels 3. The rear axle 14 is configured to transmit the power input from the transmission 12 to the rear wheel 4.

  The tractor 100 configured as described above can perform various operations such as tilling, sowing, and harvesting while traveling in a farm field. In particular, in field farming, a plurality of types of crops may be managed. The width and planting interval of cocoons vary depending on the crop. Therefore, the tractor 100 of the present embodiment is configured to be able to adjust the tread of the front wheels 3 and the rear wheels 4 in order to flexibly cope with a plurality of crops.

  Subsequently, adjustment of the tread in the tractor 100 of the present embodiment will be described. First, the adjustment of the tread of the front wheel 3 will be described with reference to FIG. FIG. 3 is a plan view showing a support structure for the front wheel 3 of the tractor 100.

  The front axle 13 includes a pair of axle cases 90 fixed to the left and right of a differential case (not shown). Each axle case 90 includes an outer cylinder 91 disposed on the inner side in the left-right direction of the fuselage, and an inner cylinder 92 disposed on the outer side.

  The end of the inner cylinder 92 on the inner side in the left-right direction of the machine body is inserted into the outer cylinder 91, and the inner cylinder 92 is slidably provided with respect to the outer cylinder 91. Therefore, the inner cylinder 92 can slide in the left-right direction with respect to the outer cylinder 91.

  A gear case 93 is turnably supported at the outer end of the inner cylinder 92 in the left-right direction. A front axle 30 to which the front wheel 3 is attached is rotatably supported by the gear case 93.

  A tread lock mechanism 80 is provided at the rear portion of the axle case 90. The tread lock mechanism 80 includes a plate 81, a detent shaft 82, and a bracket (fixing member) 83.

  As shown in FIG. 3, the plate 81 is fixed to an end of the inner cylinder 92 on the outer side in the left-right direction of the tractor 100.

  The anti-rotation shaft 82 is elongated in the left-right direction of the machine body, and one end thereof is fixed to the plate 81, and the other end is inserted into a boss portion 94 provided on the outer cylinder 91. The rotation prevention shaft 82 can prevent the inner cylinder 92, the gear case 93, and the like from rotating with respect to the outer cylinder 91. The non-rotating shaft 82 is configured to be slidable with respect to the boss portion 94, and thus can cope with tread changes.

  With the above configuration, as the inner cylinder 92 slides with respect to the outer cylinder 91, the gear case 93, the front wheel 3, the plate 81, and the rotation prevention shaft 82 are integrated with each other in the left-right direction of the tractor 100. Can slide into.

  The bracket 83 is slightly elongated in the left-right direction of the machine body, and one end thereof is fixed to the upper part of the plate 81. The bracket 83 has five mounting holes 84 formed therein. The mounting holes 84 are provided at different positions in the longitudinal direction of the plate 81 (the left-right direction of the body of the tractor 100). The number of attachment holes 84 is not limited to five, and may be six or more or four or less.

  With this configuration, the bracket 83 can be fixed to the boss portion 94 by inserting the front axle fixing bolt 85 into a selected one of the five mounting holes 84 and bolting to the boss portion 94. Further, by changing the mounting hole 84 to which the front axle fixing bolt 85 is attached, the position of the inner cylinder 92 relative to the outer cylinder 91 (and consequently the positions of the gear case 93 and the front wheel 3) can be changed in five stages.

  As shown in FIG. 3, a knuckle arm 70 is fixed to the front portion of the gear case 93. A tie rod 71 is rotatably attached to the knuckle arm 70.

  The tie rod 71 includes a pipe portion 72 and a shaft portion (fixing member) 73. One end of the shaft portion 73 is inserted into the hollow pipe portion 72 and is slidable along the longitudinal direction of the pipe portion 72. By sliding the shaft portion 73 with respect to the pipe portion 72, the length of the tie rod 71 can be changed.

  A plate member 74 arranged vertically is fixed to the end of the pipe portion 72 (the end on the side close to the gear case 93). The plate member 74 has a hole through which the tie rod fixing bolt 75 is passed. On the other hand, the shaft portion 73 is formed with five mounting holes 76 arranged at regular intervals in the longitudinal direction. However, the number of attachment holes 76 is not limited to five, and may be six or more or four or less.

  With this configuration, the tie rod fixing bolt 75 is attached to the hole of the plate member 74 of the pipe portion 72 in a state where the tie rod fixing bolt 75 is inserted into the selected one of the five attachment holes 76 of the shaft portion 73, thereby The pipe portion 72 and the shaft portion 73 of 71 can be fixed to each other. Further, by changing the attachment hole 76 to which the tie rod fixing bolt 75 is attached, the position of the shaft portion 73 with respect to the pipe portion 72 (and thus the length of the tie rod 71) can be changed in five stages.

  As described above, since the five attachment holes 84 and 76 are provided in the bracket 83 and the shaft portion 73, the position of the gear case 93 (inner cylinder 92) with respect to the outer cylinder 91 and the length of the tie rod 71 are provided. Can be adjusted in 5 stages. For example, the tread of the front wheel 3 can be shortened by one step by moving the position of the gear case 93 inward by one step (right side in FIG. 3) and shortening the tie rod 71 by one step.

  The tractor 100 according to the present embodiment is provided with a cutting angle stopper bolt 86 for avoiding the front wheel 3 from contacting the airframe 2 during turning. The cutting angle of the front wheel 3 can be adjusted by adjusting the length of the cutting angle stopper bolt 86 protruding outward in the left-right direction of the machine body. In addition, since adjustment of the cutting angle of the front wheel 3 by the cutting angle stopper bolt 86 is well-known, detailed description is abbreviate | omitted.

  Next, adjustment of the tread of the rear wheel 4 will be described with reference to FIG. FIG. 4 is a plan view showing a support structure for the rear wheel 4 of the tractor 100. FIG. 5 is a block diagram showing an electrical configuration related to tread adjustment.

  The rear axle 14 that supports the left and right rear wheels 4L, 4R includes a pair of left and right axle cases 95. The axle case 95 includes an outer cylinder 96 disposed on the inner side in the left-right direction of the fuselage, and an inner cylinder 97 disposed on the outer side. The inner cylinder 97 is configured to be slidable with respect to the outer cylinder 96, whereby the axle case 95 can be expanded and contracted. A plate 98 is fixed to the end of the inner cylinder 97 in the left-right direction.

  A hydraulic cylinder 68 is attached to each of the left and right axle cases 95 as an actuator for expanding and contracting the axle cases 95. The cylinder portion of the hydraulic cylinder 68 is fixed to the outer cylinder 96, while the tip of the cylinder rod is fixed to the plate 98.

  A detent shaft 88 is fixed to the plate 98, and the detent shaft 88 is inserted into a detent cylinder 99 fixed to the outer cylinder 96. The rotation prevention shaft 88 and the rotation prevention cylinder 99 can prevent the inner cylinder 97 and the like from rotating with respect to the outer cylinder 96.

  With the above configuration, as the inner cylinder 97 slides with respect to the outer cylinder 96, the rear wheel 4, the plate 98, and the rotation prevention shaft 88 are integrally slid in the left-right direction of the tractor 100. Can do.

  The hydraulic cylinder 68 is connected to the hydraulic pump 66 through an appropriate hydraulic circuit as shown in FIG. A flow path switching valve 67 is disposed in the hydraulic circuit. The hydraulic cylinders 68 are provided in a pair corresponding to the left and right rear wheels 4 </ b> L and 4 </ b> R, and flow path switching valves 67 are provided corresponding to the respective hydraulic cylinders 68. With this configuration, the hydraulic cylinder 68 is extended or shortened by the pressure oil switched by the flow path switching valve 67, and accordingly, the rear wheels 4 </ b> L and 4 </ b> R are moved outward or inward in the left-right direction of the body 2. As described above, the tread of the rear wheel 4 can be automatically adjusted.

  Position sensors 65 for detecting the position of the rear wheel 4 are provided at appropriate positions of the rear axle 14 corresponding to the left and right rear wheels 4L and 4R. The position sensor 65 is configured, for example, as a sensor that can detect a recess (not shown) formed in the rotation prevention shaft 88 and is electrically connected to the control unit 60.

  As shown in FIG. 5, the tractor 100 of this embodiment includes a control unit 60 for controlling the adjustment of the tread of the rear wheel 4 and the display of the monitor device 50. This control part 60 is comprised as a computer provided with CPU as a calculating part and ROM and RAM as a memory | storage part.

  The control unit 60 switches the flow path switching valve 67 in accordance with an instruction input by the operator operating the monitor device 50 described later, and drives the hydraulic cylinder 68 to extend / shorten. Further, the control unit 60 displays the actual value of the tread of the rear wheel 4 detected by the position sensor 65 and information on the rear wheel 4 during the tread adjustment on the monitor device 50 so that the operator can check the information. Can do.

  Next, the monitor device 50 installed in the vicinity of the driver's seat 9 in the tractor 100 of the present embodiment will be described.

  As shown in FIG. 6, the monitor device 50 includes a display 51 as a display unit, an operation tool 52 as an operation unit, and five command buttons 54.

  The display 51 is composed of a liquid crystal panel and is disposed at a substantially central position of the monitor device 50. The display 51 can display various information related to traveling and work of the tractor 100.

  The operation tool 52 is provided in the upper right part of the monitor device 50. The operation tool 52 is configured to be capable of rotating in both directions and to be pushed in.

  The rotation detection unit 52a illustrated in FIG. 5 is configured as, for example, a rotary encoder that can detect the rotation of the operation tool 52. The rotation detection unit 52 a can detect the rotation of the operation tool 52 for each predetermined angle and output a detection signal to the control unit 60.

  The push detection unit 52b is configured as, for example, a micro switch that can detect the push of the operation tool 52. The push detection unit 52 b can detect the push of the operation tool 52 and output a detection signal to the control unit 60.

  With the operation tool 52, the operator can give various instructions to the control unit 60. Specifically, the operator rotates the operation tool 52 to move the cursor or highlight display portion displayed on the display 51 between a plurality of items, thereby selecting a desired item from the plurality of items. Can be performed (hereinafter sometimes referred to as a selection operation). In addition, the operator can perform an operation of confirming the selection made by the above selection operation (hereinafter sometimes referred to as a confirmation operation) by pushing in the operation tool 52.

  The command buttons 54 are provided on the upper part of the monitor device 50 side by side. By pressing the command button 54, the operator can instruct the control unit 60 to display the command displayed at the position corresponding to each command button 54 on the screen displayed on the display 51.

  Next, the display on the monitor device 50 when adjusting the tread of the front wheel 3 will be described in detail.

  When activated, the monitor device 50 displays a home screen as shown in FIG. Various menus such as “tractor information”, “tractor setting”, and “power tread” are displayed side by side on the home screen. Each menu is also displayed with an icon for allowing the operator to easily understand the contents of the menu.

  An operator who desires to change the tread of the front wheel 3 operates the operation tool 52 to display the bolt attachment support screen (FIG. 10) on the display 51.

  Specifically, the operator first rotates the operation tool 52 to move the highlighted display portion on the display 51 to the “power tread” menu, thereby selecting the menu. For the convenience of expression in the drawing, in FIG. 7, the highlight display is expressed by hatching. Then, the operator confirms the selection of the “power tread” menu by pushing the operating tool 52 in a state where the “power tread” menu is highlighted as shown in FIG. Since the “OK” command is displayed on the fourth from the left on the upper end of the home screen, the selection of the menu is determined not only by pressing the operation tool 52 but also by pressing the fourth command button 54d from the left. It can also be done by pressing.

  When the “power tread” menu is selected as described above, the screen displayed on the display 51 is switched to the tread adjustment screen of the rear wheel 4 shown in FIG. This tread adjustment screen is for adjusting the positions of the left and right rear wheels 4L, 4R to realize a desired tread. When the tread adjustment of the rear wheel 4 is desired, the operator appropriately operates the operation tool 52 to select a desired tread value from among a plurality of tread values V displayed side by side on the screen. Thereafter, by pushing the operating tool 52 in a state where the “adjustment start” button B1 for instructing the actual adjustment of the tread is highlighted (or by pressing the command button 54d), the tread of the rear wheel 4 is adjusted. Adjustments can be made automatically.

  When adjusting the tread by operating the screen of FIG. 8, the positions of both the left and right rear wheels 4L, 4R are adjusted. In this embodiment, the position of either one of the left and right rear wheels 4L, 4R is adjusted. You can also adjust only. The position adjustment of only one wheel of the rear wheel 4 is performed by performing a confirmation operation in a state where “next page” is selected on the tread adjustment screen of FIG. 8 and displaying the tread adjustment screen of only one wheel shown in FIG. be able to. The operation on the screen of FIG. 9 includes the tread adjustment screen for both the left and right rear wheels 4L and 4R shown in FIG. 8 except that it is necessary to select which of the left and right rear wheels 4L and 4R is to be adjusted. It is substantially the same.

  When the confirmation operation is performed in a state where “next page” is selected on the one-wheel tread adjustment screen (rear wheel 4) shown in FIG. 9, the display on the display 51 is a bolt installation support screen for adjusting the tread of the front wheel 3. Can be switched to.

  In the bolt attachment support screen, as shown in FIG. 10, the front wheel 3 </ b> L attached to the left side of the airframe 2 and a part of its support structure (tie rod 71, bracket 83) are viewed from directly above the tractor 100. Is graphically displayed on the right side of FIG. A plurality of tread values V1 to V5 are vertically arranged on the left side of the schematic diagram of the front wheel 3 and its support structure. A caution display area D1 is arranged at the lower end of the screen. In the caution display area D1, a message M1 is displayed to alert the operator to move the tractor 100 to a safe position when adjusting the tread.

  In the schematic diagram of the tie rod 71, five attachment positions E1 to E5 to which the tie rod fixing bolt 75 can be attached to the shaft portion 73 are displayed in a circle or a hexagon. The attachment positions E1 to E5 correspond to five attachment holes 76 formed in the shaft portion 73. In the example of FIG. 10, among the five mounting positions E1 to E5, the mounting position E5 is a hexagon, and the other mounting positions E1 to E4 are each displayed as a circle. Here, the hexagon indicates the head of the bolt. That is, the schematic diagram of the tie rod 71 shown in FIG. 10 indicates that the tie rod fixing bolt 75 should be attached to the attachment position E5.

  In the schematic view of the bracket 83, five attachment positions E11 to E15 at which the front axle fixing bolt 85 can be attached to the bracket 83 are displayed as a circle or a hexagon. The attachment positions E11 to E15 correspond to five attachment holes 84 formed in the bracket 83. In the example of FIG. 10, among the five mounting positions E11 to E15, the mounting position E15 is a hexagon, and the other mounting positions E11 to E14 are each displayed as a circle. That is, the schematic diagram of the bracket 83 shown in FIG. 10 shows that the front axle fixing bolt 85 should be attached to the attachment position E15.

  As described above, the tread of the front wheel 3 can be adjusted in five stages depending on the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85. The five tread values V <b> 1 to V <b> 5 displayed on the screen of FIG. 10 indicate tread values in each of the five stages of tread adjustment of the front wheel 3.

  In the tractor 100 of the present embodiment, five treads are displayed on the display 51 in order to easily show the correspondence between the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85 and the tread of the front wheel 3 to the operator. Each of the values V1 to V5 can be displayed in correspondence with each of the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85.

  Specifically, on the bolt attachment support screen shown in FIG. 10, the five tread values V1 to V5 are displayed in different colors. Further, the attachment positions E1 to E5 of the tie rod fixing bolt 75 are displayed in different colors, and the attachment positions E11 to E15 of the front axle fixing bolt 85 are also displayed in different colors. The display color of a certain tread value is the same as the display color of the mounting position of the tie rod fixing bolt 75 and the mounting position of the front axle fixing bolt 85 corresponding thereto.

  For example, they are displayed in the same color (for example, yellow) so that the correspondence between the tread value V1 and the corresponding mounting position E1 of the tie rod fixing bolt 75 and the mounting position E11 of the front axle fixing bolt 85 can be understood. . Similarly, each of the tread values V2, V3, V4, and V5 is displayed in, for example, orange, pink, blue, and green, and the corresponding mounting positions E2, E3, E4, and E5 of the tie rod fixing bolt 75 and the front axle fixing bolt Each of the 85 mounting positions E12, E13, E14, and E15 is displayed in orange, pink, blue, and green. For convenience of expression in the drawings, different colors are represented in FIG. 10 by hatching in different modes.

  Since the colors are associated with each other in this way, when the operator manually adjusts the tread of the front wheel 3, the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85 corresponding to the desired tread value are intuitive. Can understand. As a result, the tread can be adjusted accurately (as a result, the tie rod fixing bolt 75 and the front axle fixing bolt 85 can be attached).

  Further, in the screen of FIG. 10, each of the displayed five tread values V1 to V5 and each of the attachment positions E1 to E5 of the tie rod fixing bolt 75 are displayed in a straight line. Since the association is made by lines in this way, the correspondence relationship between them becomes easier to understand.

  Furthermore, the tractor 100 of the present embodiment is configured so that any one of the five tread values V1 to V5 displayed on the screen of FIG. 10 can be selected. When any tread value is selected, the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85 corresponding to the tread value are displayed in a hexagonal shape instead of a circle.

  Specifically, the operator selects a desired tread value from among the five displayed tread values V1 to V5 by rotating the operation tool 52, and performs a confirmation operation with the tread value selected. And the control part 60 displays the hexagon which shows the attachment position of the tie rod fixing bolt 75 and the front axle fixing bolt 85 in the attachment position corresponding to the determined tread value. Note that FIG. 10 shows a state where the lowest tread value V5 is selected from the tread values V1 to V5 arranged in the vertical direction and the confirmation operation is performed.

  As a result, when the operator manually adjusts the tread of the front wheel 3, the installation position of the tie rod fixing bolt 75 and the front axle fixing bolt 85 can be easily shown to the operator simply by selecting a desired tread value from the list. it can. As a result, the tie rod fixing bolt 75 and the front axle fixing bolt 85 can be more accurately attached according to the tread value desired by the operator. In addition, since it is not necessary to perform work while referring to an instruction manual or the like, work efficiency can be improved.

  Next, a stopper bolt adjustment support screen for adjusting the tread of the front wheel 3 will be described with reference to FIG.

  When the confirmation operation is performed in a state where “next page” is selected on the screen of FIG. 10, the display 51 displays a stopper bolt adjustment support screen for adjusting the cut angle stopper bolt 86 as shown in FIG. Is done.

  The stopper bolt adjustment support screen indicates to the operator the mounting length of the cutting angle stopper bolt 86 corresponding to each tread value V1 to V5. In this stopper bolt adjustment support screen, as shown in FIG. 11, five tread values V1 to V5 are vertically arranged on the left side of the screen, and the front wheel 3L and a part of the support structure are schematically shown on the right side of the screen. Is displayed graphically. And on the right side of the tread values V1 to V5, specific values of the projecting lengths L1 to L5 of the cutting angle stopper bolt 86 with respect thereto are displayed.

  As shown in FIG. 11, the schematic diagram of the support structure of the front wheel 3 displayed on the display 51 includes an enlarged view of the cutting angle stopper bolt 86, and the length from where to where is the protruding length L. It is shown in the figure. Therefore, the operator can accurately adjust the protruding length of the cutting angle stopper bolt 86.

  Furthermore, in the tractor 100 of this embodiment, in order to display the corresponding relationship between the five tread values V1 to V5 and the protrusion lengths L1 to L5 of the cutting angle stopper bolt 86 in an easy-to-understand manner, the respective tread values V1 to V1 are displayed. V5 and the corresponding protrusion lengths L1 to L5 of the cutting angle stopper bolt 86 are displayed in the same color. Specifically, five tread values V1 to V5 are displayed in the order of yellow, orange, pink, blue, and green from the top, and the protrusion lengths L1 to L5 of the cutting angle stopper bolts 86 corresponding to them are the top. To yellow, orange, pink, blue, green.

  Thereby, when the operator adjusts the tread of the front wheel 3, the protruding length of the cutting angle stopper bolt 86 corresponding to the desired tread value can be confirmed on the display 51. As a result, the protruding length of the cutting angle stopper bolt 86 corresponding to the adjusted tread value can be easily and accurately adjusted.

  Next, the tread change by attaching the disk 31 and the rim 32 of the front wheel 3 will be described. As shown in FIG. 3, the front wheel 3 included in the tractor 100 of the present embodiment includes a disk 31 fixed to the front axle 30 and a rim 32 fixed to the disk 31. A rubber tire is attached to the rim 32. The rim 32 is configured to be detachable from the disk 31 and can be fixed by selecting one from two different positions in the left-right direction of the machine body. Further, the disk 31 can be fixed to the front axle 30 with the front and back reversed, and the rim 32 can also be fixed to the disk 31 with the front and back reversed.

  As a result, the tractor 100 according to the present embodiment has a plurality of (eight in the present embodiment) positions of the front wheel 3 depending on the combination of the fixed position of the rim 32 with respect to the disk 31 and the front and back of the rim 32 and the disk 31. Can be realized. In the following description, the fixing position of the rim 32 with respect to the disk 31, the direction in which the rim 32 is fixed, and the direction in which the disk 31 is fixed with respect to the front axle 30 are collectively referred to as a “fixed state”. is there.

  Incidentally, the tread adjustment of the front wheel 3 by the disc 31 and the rim 32 can be performed independently of the tread adjustment by the tie rod fixing bolt 75 and the front axle fixing bolt 85 described above. Therefore, in order to accurately realize the tread value of the front wheel 3 as intended by the operator, it is necessary to make an adjustment in consideration of how the disk 31 and the rim 32 are fixed.

  In this regard, the tractor 100 according to the present embodiment is configured such that the fixed state of the disk 31 and the rim 32 in the front wheel 3 can be input to the monitor device 50. 10 and 11 are configured to display values calculated based on the inputted fixed state as the five tread values V1 to V5. As a result, the tread adjustment of the front wheel 3 can be performed more accurately.

  Hereinafter, the operation of the monitor device 50 when the fixed state of the disk 31 and the rim 32 is changed will be described. When the operator changes the fixing state of the front wheel 3, a new fixing state can be designated on the rim fixing selection screen shown in FIG. This rim fixation selection screen can be displayed by performing a confirmation operation in a state where “next page” is selected on the stopper bolt adjustment support screen of FIG.

  In the rim fixing selection screen of FIG. 12, eight states (fixed states) related to fixing of the disk 31 and the rim 32 of the front wheel 3 are displayed in a selectable manner with reference tread values corresponding thereto.

  Here, the reference tread value is a tread value when the tie rod fixing bolt 75 and the front axle fixing bolt 85 are attached to a standard attachment position (for example, an attachment position at the time of factory shipment) determined by the tractor manufacturer. It is. In the tractor 100 of the present embodiment, the standard attachment position is the attachment position E1 for the tie rod fixing bolt 75, and the attachment position E11 for the front axle fixing bolt 85. Therefore, the reference tread value corresponds to the shortest tread value among the five tread values. However, other mounting positions may be standard mounting positions.

  In the rim fixing selection screen, as shown in FIG. 12, eight types of fixed states of the disk 31 and the rim 32 of the front wheel 3 are displayed side by side. In the schematic diagram of each front wheel 3, the center line c1 of the front wheel 3 is displayed, and a reference tread value corresponding to the fixing position of the disk 31 and the rim 32 of the front wheel 3 is near the center line c1. It is displayed.

  The operator can also refer to this rim fixing selection screen before performing the operation of changing the fixing state of the disk 31 and the rim 32 of the front wheel 3. In this case, in order to achieve a desired reference tread value, it is possible to easily confirm how the disk 31 and the rim 32 should be fixed before performing the work.

  By operating the operation tool 52, the operator selects one of the eight schematic diagrams displayed on the display 51 that matches the fixed state of the new disk 31 and the rim 32. Specifically, the schematic diagram highlighted in the eight schematic diagrams is switched by rotating the operation tool 52, and the schematic diagram matching the new fixed state is confirmed in the highlighted state. Perform the operation. In FIG. 12, the highlight display is indicated by hatching for the convenience of expression in the drawing. Thereby, it is possible to instruct the controller 60 of the fixed state of the disk 31 and the rim 32.

  The control unit 60 recalculates the tread values V1 to V5 displayed on the screens of FIGS. 11 and 12 based on the fixed state of the selected disk 31 and rim 32 (in other words, the above-described reference tread value). The shortest tread value V1 coincides with the reference tread value, and other tread values V2 to V5 can be easily calculated using a geometrical relationship. Omitted. As described above, the operator can accurately perform the adjustment work for realizing the desired tread value.

  Next, restrictions on tread adjustment of the front wheel 3 will be described. For example, when a work device such as a front loader is mounted on the front part of the tractor, if the tread of the front wheel 3 is made too large, the front wheel 3 interferes with the work device or ensures a cutting angle of the front wheel 3 for steering. There is a risk that it will not be possible. Therefore, it is desirable to show the operator in an easy-to-understand manner that the tread adjustment of the front wheel 3 is limited.

  In this regard, in the tractor 100 of the present embodiment, when the control unit 60 detects that the work device is mounted, on the rim fixation selection screen (FIG. 12), The reference tread can be displayed for the operator to understand. As a specific display method, it is conceivable to display a suitable fixed state and reference tread with appropriate marks (not shown) or to display a non-conforming fixed state and reference tread in gray out. . Further, only the compatible fixed state and the reference tread may be narrowed down and displayed.

  In addition, the work device mounted on the tractor 100 can be detected by the control unit 60 appropriately communicating with the controller of the work device, for example.

  Thereby, when the working device is mounted, the operator can easily grasp the fixed state and the reference tread of the disk 31 and the rim 32 of the front wheel 3 that can be adapted to the working device.

  When the confirmation operation is performed with “next page” selected on the screen of FIG. 12, the display on the display 51 returns to the tread adjustment screen of the rear wheel 4 of FIG. In this way, by performing the “next page” operation, the display of the screen can be switched cyclically. Further, by operating the “previous page”, the screen can be switched in the reverse order to the case of the “next page”. Through the page transition as described above, the operator can obtain a variety of information by displaying a desired screen.

  As described above, the tractor 100 according to the present embodiment includes the shaft portion 73 of the tie rod 71, the bracket 83 of the tread lock mechanism 80, and the display 51 that displays information related to the tread. The shaft portion 73 and the bracket 83 have a plurality of attachment positions E1 to E5 and E11 to E15 for adjusting the tread of the front wheel 3. The display 51 can display a plurality of tread values V1 to V5 and a plurality of the mounting positions E1 to E5 and E11 to E15 for realizing each tread value in association with each other.

  As a result, when the operator manually adjusts the tread of the front wheel 3, it is intended to attach the tie rod fixing bolt 75 and the front axle fixing bolt 85 to any of the plurality of attachment positions only by confirming the display 51. Whether the tread value can be realized can be easily grasped. Therefore, the tread adjustment of the front wheel 3 can be performed easily and accurately.

  Further, the tractor 100 according to the present embodiment includes an operation tool 52. The operation tool 52 can be operated by the operator so as to select any one of the plurality of tread values V1 to V5 displayed on the display 51. The display 51 graphically displays a plurality of mounting positions E1 to E5 and E11 to E15, and the mounting position corresponding to the tread value selected by the operator's operation is different from other mounting positions (that is, hexagonal). Can be displayed.

  Thereby, when adjusting the tread of the front wheel 3, by selecting the tread value intended by the operator, the mounting positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85 corresponding to the tread value are displayed in an easy-to-understand manner. Therefore, the tread adjustment of the front wheel 3 can be performed more accurately.

  Further, in the tractor 100 of the present embodiment, the front wheel 3 includes a disk 31 and a rim 32 fixed to the disk 31. The rim 32 is configured to be fixable to the disk 31 at a plurality of fixing positions. The tread values V1 to V5 displayed on the display 51 change according to the fixed position of the rim 32 with respect to the disk 31 (in other words, the fixed state).

  Thus, even when the tread is changed depending on the fixed position between the rim 32 and the disk 31, the operator can accurately know the correspondence between the tread value and the mounting position.

  Further, in the tractor 100 of the present embodiment, the display 51 can display a plurality of fixed positions (the fixed state) of the rim 32 with respect to the disk 31 and the reference tread values corresponding to the fixed positions. is there.

  Thereby, the operator can easily confirm how the rim 32 should be fixed to the disk 31 in relation to the desired reference tread value. As a result, the efficiency of the tread adjustment work can be improved.

  Further, in the tractor 100 of the present embodiment, the display 51 displays a reference tread value that can be adapted to the work device among a plurality of reference tread values when the work device is mounted on the body 2.

  Thereby, by referring to the display on the display 51 and attaching the front wheel 3, contact between the attached front wheel 3 and the work device can be prevented.

  The preferred embodiment of the present invention has been described above, but the above configuration can be modified as follows, for example.

  In the above embodiment, the tread values V1 to V5 and the mounting positions E1 to E5 and the mounting positions E11 to E15 are displayed in yellow, orange, pink, blue, and green colors on the display 51. It is also possible to change.

  In the above-described embodiment, the attachment positions of the tie rod fixing bolt 75 and the front axle fixing bolt 85 corresponding to the tread value selected and confirmed are displayed as hexagons. However, as long as it can be distinguished from other mounting positions (in a different manner), it may be displayed in another shape, or a circle may be blinked.

  In the tractor 100 of the above embodiment, the tread adjustment of the rear wheel 4 is performed by the hydraulic cylinder 68, but it can be changed to a configuration in which this is adjusted manually. In this case, the monitor device 50 can be configured to display a screen similar to FIG. 10 or the like in order to manually adjust the tread of the rear wheel 4.

  In the above-described embodiment, when the work device is mounted on the tractor 100, the reference tread that can be adapted is displayed (differentiated). However, instead of or in addition to this, among the tread values V1 to V5 (in other words, the mounting positions E1 to E5 of the tie rod fixing bolt 75 and the mounting positions E11 to E15 of the front axle fixing bolt 85), the working device. It is also possible to display what can be adapted to (differentiated).

  The operation of the monitor device 50 is not limited to the operation tool 52 and the command button 54, but may be configured to be performed by another member for operation. For example, the display 51 may be configured as a touch panel, and the monitor device 50 may be operated by an operator touching the touch panel with a finger.

  The present invention can also be applied to work vehicles other than tractors.

2 Airframe (car body)
3 (3L, 3R) Front wheel (wheel)
50 Monitor device 51 Display (display unit)
52 Operation tool (operation unit)
54 Command button (operation unit)
73 Shaft (fixing member)
83 Bracket (fixing member)
100 Tractor (work vehicle)

Claims (5)

A work vehicle comprising: a rear wheel provided with an actuator for automatically adjusting a tread of a wheel; and a front wheel in which the tread is adjusted via a fixing member having a plurality of attachment positions,
A display unit for displaying information on the tread;
The display unit
Information about the tread of the rear wheel with the actuator can be displayed;
A work vehicle capable of displaying a plurality of tread values of the front wheels and the mounting positions for realizing the tread values in association with each other. The work vehicle according to claim 1,
An operation unit operable by an operator to select any one of the plurality of tread values displayed on the display unit ;
A control unit that controls adjustment of the tread of the rear wheel according to an instruction input by operating the operation unit;
With
The display unit graphically displays a plurality of the mounting positions of the fixing member for adjusting the tread of the front wheel, and displays the mounting position corresponding to the tread value selected by an operator's operation in the other A work vehicle capable of being displayed in a mode different from an attachment position. The work vehicle according to claim 1 or 2,
The front wheel is provided with a disk, and a rim fixed to the disc, and
The rim is configured to be fixable to the disk at a plurality of fixed positions,
The work vehicle according to claim 1, wherein the tread value displayed on the display unit changes in accordance with the fixed position of the rim and the disc. A work vehicle according to any one of claims 1 to 3,
The front wheel is provided with a disk, and a rim fixed to the disc, and
The rim is configured to be fixable to the disk at a plurality of fixed positions,
The work vehicle characterized in that the display unit can display a plurality of tread values at at least one of the attachment positions in association with the fixed positions for realizing the plurality of tread values. A work vehicle according to any one of claims 1 to 4,
The said display part displays the said tread value which can be adapted to the said working apparatus among several said tread values, when a working apparatus is mounted | worn with the vehicle body, The working vehicle characterized by the above-mentioned.

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